Three masses `m_1 = m ,m_2 = 2m and m_3 = 3m` are hund on a string passing over a frictionless pulley as shown in Figure . The mass of the string in negligible . The system is released from rest.

 The tension in the string between masses `m_2 and m_3` is 

Three masses m_1 = m ,m_2 = 2m and m_3 = 3m are hund on a string passing over a frictionless pulley as shown in Figure . The mass of the string in negligible . The system is released from rest. The tension in the string between masses m_1 and m_2 is

Three masses m_1 = m ,m_2 = 2m and m_3 = 3m are hund on a string passing over a frictionless pulley as shown in Figure . The mass of the string in negligible . The system is released from rest. If a_1 a_2 and a_3 are the accelerations of masses m_1, m_2 and m_3 respectively, then

Two masses m and M(m lt M) are joined by a light string passing over a smooth and light pulley (as shown)

The block of mass m is at rest. Find the tension in the string A .

Three equal weights of 3 kg each are hanging on a string passing over a frictionless pulley as shown in figure. The tension in the string between masses II and III will be (Take = 10m//sec^(2) )

Two masses m_1=5kg and m_2=4.8kg tied to a string are hanging over a light frictionless pulley. What is the acceleration of the masses when left free to move?

Two blocks of masses m and 2m are connected by a light string passing over a frictionless pulley. As shown in the figure, the mass m is placed on a smooth inclined plane of inclination 30° and 2m hangs vertically. If the system is released, the blocks move with an acceleration equal to :

Two masses m and M(gt m) are joined by a light string passing over a smooth light pulley. The centre of mass of the system moves with an acceleration

Three blocks of masses m_(1)=4kg, m_(2)=2kg, m_(3)=4kg are connected with ideal strings passing over a smooth, massless pulley as shown in figure. The acceleration of blocks will be (g=10m//s^(2))

Two masses m_(1) and m_(2) ( m_(2) gt m_(1)) are hanging vertically over frictionless pulley. The acceleration of the two masses is :